Fundamentals of Control r1 3

December 14, 2017 | Author: Marco Antonio | Category: Control Theory, Control System, Brake, System, Force
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The Fundamentals of Control Theory An Intuitive Approach from the Creator of Control System Lectures on YouTube

Brian Douglas

Revision 1.3

Copyright © 2016 Brian Douglas

Licensed under the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License (the “License”). You may not use this file except in compliance with the License. You may obtain a copy of the License at http://creativecommons.org/licenses/by-nc-sa/4.0. Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an “AS IS ” BASIS , WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND,

either express or implied. See the License for the

specific language governing permissions and limitations under the License.

Revision, 1.3 Printing Date, May 18, 2016

Contents

Preface

i

I

The Big Picture

1

1

The Control Problem

2

1.1

What is a system? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

2

1.2

The three different problems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

7

1.2.1

The system identification problem . . . . . . . . . . . . . . . . . . . . . . . . . . .

7

1.2.2

The simulation problem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10

1.2.3

The control problem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12

2

1.3

Why do we need a feedback control system? . . . . . . . . . . . . . . . . . . . . . . . . . . 13

1.4

What is a control system? . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 16

1.5

The First Feedback Control System . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20

1.6

Try This! . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27

Transfer Functions

30

2.1

LTI Systems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35

2.2

Impulse Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 40

2.3

Convolution Integral . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45

2.4

The Frequency Domain and the Fourier Transform . . . . . . . . . . . . . . . . . . . . . . 54

2.5

Convolution versus Multiplication . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 61

2.6

The s domain and the Laplace Transform . . . . . . . . . . . . . . . . . . . . . . . . . . . 66 2.6.1

Remember the Fourier Transform! . . . . . . . . . . . . . . . . . . . . . . . . . . . 66

2.6.2

The s Plane . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69

2.6.3

The Laplace Transform . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72

2.7

Putting this all Together: Transfer Functions . . . . . . . . . . . . . . . . . . . . . . . . . . 81

2.8

Try This! . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81

Appendices

83

A

84

How to Provide Feedback

A.1 Filling out the Create issue screen . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85

B

Transforms

87

B.1 Fourier Transform . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87

Preface

Welcome to the Fundamentals of Control Theory! This book is the direct result of my online video lectures on control system theory and the overwhelming positive feedback and encouragement I’ve received from my viewers to write a book. I started my YouTube channel (https://youtube.com/ControlLectures) because I was frustrated by the lack of straightforward and easy to understand videos on the topic and felt that what some students needed was a more practical and intuitive approach to understanding the material. This book is an extension of that idea. I’m releasing this book one section at a time. Similar to how I create new videos on a monthly basis I will add new content to the book on a monthly schedule. This allows me to get the early chapters out there helping people right away while being able to have your reactions and responses influence the later chapters. So with that in mind, as I write this book there are four goals I hope to accomplish that I think will make it a valuable resource for any aspiring controls engineer.

1. Provide an intuitive understanding - I want to start by saying there already exist several fantastic control system textbooks. Therefore, I don’t think I would be able to write a useful book in this crowded field by presenting the same information in the same formal format. So I’m not going to try to duplicate them, instead I’m creating a book that is a bit different. The language is a little less formal - it’s written as though we’re having a coni

PREFACE

ii

versation - and the mathematical proofs are a little more casual. However, I claim that what you’ll learn from this book is just as useful as the existing textbooks because you’ll gain an overall understanding of the problem and how to approach it.

2. Update the book frequently - One of the luxuries of making an eBook is that I can distribute updates quickly and cheaply. I am approaching this book more like a distribution of software, where bug fixes and minor layout changes can be updated and distributed as a point release (minor update) rather than a major new edition. With this model I can fix bugs and add content on a regular basis so that readers will always have the most up to date revision.

3. Allow the readers to participate in improving the book - How many times have you come across an error in a textbook or a really confusing explanation and wished you had a way of providing feedback easily to the author? I want to hear that feedback for this book! It is your feedback that will drive the quick point releases and help me create the most useful textbook possible. This is why I provide a simple ticketing system where you can give me feedback on errors in calculations, vague or confusing explanations, and missing content. I ask that you please let me know any time you come across something in the book so that I can fix it and it won’t confuse the next round of readers. For details on how to provide that feedback see Appendix A.

4. Make the book as inexpensive as possible - Lastly, college textbooks are expensive and if I want this book to really help students all over the world then it needs to be affordable. I understand that students don’t have

PREFACE

iii

much money1 and so having to buy several $180 books each semester is not high on your list of fun activities. That is why I’m releasing this book under the Creative Commons License and giving the book out for free to anyone who supports my work (which includes the videos I make) through konoz.io. You can get to my creator’s page at konoz with this link.

https://konoz.io/briandouglas For any amount of support (even if it’s just $1) you will have continuous access2 to the book and to all future updates. If you decide you no longer want to support me you will still get to keep and use the book you already have. So theoretically you could get the book for as little as $1. I think this is a good way of allowing people to decide how much they want to support me while not excluding people who really want to learn control theory but can’t afford the book. Engineering problems are inherently multi-disciplinary and so you have your choice of learning any number of specialized fields that will allow you to contribute to a project. But I think the best reason to learn control theory is that it is the glue that combines all other engineering fields and by understanding the fundamentals of control theory it opens the door for you to understand all of those other fields at a more basic level. It is actually a fascinating subject and through this book I hope to infect you with the same enthusiasm for the subject that I have. 1 When

I was in college I had so little spending money by the end of the semester that I would buy large bags of white rice and a few condiments and then eat rice at every meal; rice and honey, rice and hot sauce, rice and mustard. 2 Access means you get to copy the PDF onto your computer, put it on your eReader, or print it out, make copies of it, use it in your presentation, or part of your lecture, and even share it with your friends!

PREFACE

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Chapter 1 describes the control problem. This chapter sets the stage for what we’re trying to accomplish as control system engineers and defines the terms that we use throughout this book. Chapter 2 introduces a way of describing a system mathematically using transfer functions. This chapter builds up the fundamental concepts behind transfer functions and sets the foundation that we will build on going forward. Once written, the rest of the book will cover transfer functions, how we represent systems with block diagrams, and concepts like system stability, time, frequency, discrete domains, and system identification. We’ll then cover how we use specialized plotting tools like Root Locus, Nyquist plots, and Bode plots to analyze and understand our system. Later chapters will describe compensation techniques like lead and lag, loop shaping, and PID. By the end of this book I hope you realize that control system theory is so much more than just tuning a PID controller or getting an inverted pendulum to stand upright. It’s building models of your system and simulating it to make predictions, it’s understanding the dynamics and how they interact with the rest of the system, it’s filtering out noise and rejecting outside disturbances, it’s designing or selecting proper sensors and actuators, and it’s testing your system to ensure it’ll perform as expected in an unexpected environment. Now before you proceed any further I want to thank you for reading this book3 and for supporting me to keep making improvements to this text. I hope you gain a better intuition into control theory and ultimately you become a more well-rounded 3 and

the preface! Who reads the preface anyway?

PREFACE

engineer.

Brian Douglas

v

1 The Control Problem

In this chapter we’ll get an overview of the big picture problem that we’re trying to solve as control system engineers. This will give context to everything we’ll cover in later chapters and in doing so I think will help you understand why you are learning the topics presented in this book.

1.1

What is a system?

To begin we describe exactly what a system is. The concept is really straight forward but since the term is so generic we tend to apply the word to describe just about everything. This can get confusing to someone new to the field when we refer to something called the control system which is then used to control the actual system and when put together the two parts make yet another larger system. As someone learning control theory the question becomes what system am I working on? To answer this let’s start with the definition and work from there. A system is a collection of interconnected parts that form a larger more complex whole.

Engineering projects are typically complex. Dividing complex projects into smaller pieces, or systems, simplifies the problem because it allows people to specialize in their functional area and not have to be a generalist in all areas. Therefore, as a specialist you might be working on just one of the interconnected parts that form 2

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the entire system. However, there might be many layers of complexity such that the small part you are working on is actually a complex system in its own right! The same is true for specialists in control theory. As a control engineer your goal is to create something that meets the functional or performance requirements you set for the project. In general, we refer to the collection of the interconnected parts that are created specifically to meet these requirements as the control system. For any project other than the very simplest ones, however, the control system again might be a collection of interconnected parts that require specialists like sensor experts, actuators experts, digital signal processing experts, or state estimation experts. To illustrate this let’s imagine that you have accepted a job at an automotive company and you will be working on the braking system. At first glance you might suspect that you will be involved in all parts related to slowing the vehicle. However, there are many parts to the braking system on your car and it takes many different specialists to design the complete product. The most obvious component is the disc brake assembly in each wheel. This is the part that is actually converting the car’s kinetic energy into heat energy and slowing down the vehicle. Yet the disc brakes are small systems on their own because they are made up of rotors, calipers, brackets, shielding, fasteners and hoses which allow the disc brakes to function correctly.

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Engaging the brakes requires the brake hydraulic system which is responsible for transferring the pressure applied by your foot at the brake pedal through the power booster, dual master cylinder and the combination valve and finally to the brake calipers at each of the four wheels.

There is the mechanical parking brake system that bypasses the hydraulic system with a secondary cable path to the brakes and the brake light system that is responsible for lighting the tail lights and that annoying dashboard light that tells you the parking brake is engaged.

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Finally there are any number of electronic brake control systems that override the human input to keep the vehicle from skidding on slick surfaces or a distracted driver from crashing into the car in front of them.

All of these smaller systems - the brakes, hydraulics, parking brake, lighting, and electronic controls - are the interconnected parts that form the larger and complete braking system. Furthermore, the braking system is just one of many interconnected parts that create the car itself. As a control specialist in the brake department you might be responsible for writing and testing the algorithm for the electronic brake control system but have very little impact on, say, the cable routing for the parking brake. Defining different systems allows complex projects to exist but it does create this potential confusion of everything being called a system. To mitigate this, depending on the field you work in, there is usually a term for each of the different hierRevision 1.3

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archical levels of complexity in a project. For example, a couple of parts creates a component which in turn creates a subsystem which then finally creates a system. I’m not going to try to define where the boundaries are between each of those because every industry and company does it differently. However, it is important that you recognize this and are clear what someone is specifically referring to when they ask you to design a controller for some system. In this book I will try to be explicit when I say system because what I’m referring to will change based on the context of the problem. In general, we will represent any system graphically as a box. Arrows going into the box represent external inputs acting on the system. The system then responds over time to these inputs to produce an output - which are arrows leaving the box.

Typically we define the system in the box with a mathematical model that describes its equations of motion. At the moment we don’t need to worry about the math, the most important thing is that we understand what this box means physically. For example the system could be really simple like a single disc brake with the inputs being the force of the hydraulic fluid and the output being the temperature of the rotor. Or the system could be complex like the entire car and have hundreds of inputs and thousands of outputs.

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In both cases though our graphical representation would look similar, a box with arrows going into it and arrows coming out. Later we will string several systems (boxes) together to create complex block diagrams. These block diagrams will contain the relevant interconnected parts of an even larger system. For the next section, however, this single box representation will give us some insight into three different types of problems that we’ll face throughout this book and as practicing engineers.

1.2

The three different problems

You will notice that there are three parts to our simple block diagram; there is the box itself which represents a system, the inputs that are driving the system, and the outputs that the system generates. At any given time one of the three parts are unknown to you, and whichever part you don’t know defines the problem that you are trying to solve. 1.2.1

The system identification problem

As a student you are usually given a mathematical model of your system at the start of your problem and then asked to perform some analysis of it or asked to Revision 1.3

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design a control system around it. However, as a practicing engineer you won’t always be given a model of your system1 , you’ll need to determine that yourself. Determining the mathematical model is done through a process called system identification.

You might be doing system identification if you find yourself asking the following questions: • How can I model the system that I’m trying to control? • What are the relevant dynamics for my system (what should I model)? • What is the mathematical equation that will convert my known inputs into my measured outputs? There are at least two ways that we can answer these questions. The first is referred to as the black box method. Imagine you were given a box that you could not open but you were asked to make a model of what was inside. You could subject what is in the box to various known inputs, measure the resulting outputs and then infer what’s inside the box based on the relationship between the two.

1 In

fact you’ll almost never be given a model since what you’re working on is very likely the first of its

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The second way to perform system identification is referred to as the white box method. Imagine now you were able to see exactly what was inside the box - all of the electronics, mechanisms, and software. Knowing the components of the system you could write the mathematical equations of the dynamics directly. This is exactly what you’re doing when you use Newton’s equations of motion or you are determining the equations of motion based on the energy in the system.

You might argue that you don’t need to know the inputs or the outputs in order to write out some equations of motion, but that’s not true. Even with this white box method there will be a need to set up a test with known inputs and measured outputs so you can get the unique parameters for your system. For example, you might need to model a linear spring - the equation of motion is well known - but will have to perform a stretch test to determine the exact spring constant for it2 . 2I

know you might be thinking, ‘but I’ve been given the spring constant from the manufacturer so I don’t have to perform that test!’ And to that I have two responses, 1) are you really going to trust the manufacturer’s datasheet if that parameter is important to you? and 2) if you are fine with the accuracy stated in the datasheet then this is a case where you were given the model of your system, just like in school! Revision 1.3

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For this test the input is the force that the mass is exerting on the spring and the output is the stretched length of the spring. We can tell from the relationship between the input forces and the output lengths that the spring constant is 2 Newtons per meter. System identification is an important part of designing a control system and so we’ll discuss it in greater detail in a later chapter. 1.2.2

The simulation problem

If we know the inputs and the system dynamics then we can predict how the system will behave through simulation. This problem is interesting because you’ll likely spend the majority of your design time in this stage. The trick here is figuring out what is the set of meaningful inputs and their ranges so that you have a complete idea of how your system behaves.

You might need to run a simulation if you find yourself asking the following questions: • Does my system model match my test data? Revision 1.3

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• Will my system work in all operating environments? • How does my system behave if I drive it with potentially destructive commands? To see how simulation is important imagine you have a very good model of a passenger airplane and you’re designing a pitch control system for it. You want to know how your system behaves across the entire operating envelope and you’re weighing the different approaches you could take. You could use a test airplane and fly in it every operating condition it could expect to see during its life and directly observe its behavior. The problem with this is that the operating envelope is huge3 and flight test campaigns are expensive and so minimizing the amount of flight time could save your project a lot of money. Also flight tests can be dangerous to perform if you are trying to push the limits of your system to see how it reacts. Rather than risk project budget and possible human life it makes more sense to simulate your system.

3 You

need to make sure that your pitch control system will function across all operating altitudes, wing angles of attack, air speeds, center of gravity locations, flap settings, and weather conditions. Revision 1.3

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1.2.3

The control problem

If we know the system and we know how we want the system outputs to behave then we can determine the appropriate inputs through various control methods. This is the control problem - how do we generate the appropriate system input that will produce the desired output? Control theory gives you the tools needed to design a control system which will generate the required input into the system. Without control theory the designer is relegated to choosing a control system through trial and error.

You might need to design a control system if you find yourself asking the following questions: • How can I get my system to meet my performance requirements? • How can I automate a process that currently involves humans in the loop? • How can my system operate in a dynamic and noisy environment? This book will lay out the fundamental tools needed to solve the control problem and in doing so I think you’ll find that control theory can be challenging but a lot of fun and very intuitive. Before we move on to learning these tools let’s take a step back and describe in more detail why we need control systems in the first place.

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1.3

Why do we need a feedback control system?

Let’s start with our simple system block diagram, but now the box isn’t just any system, it’s specifically a system that we want to control. From now on we’ll refer to the system that is being controlled as the process4 . The inputs into the process are variables that we have access to and can change based on whichever control scheme we choose and so we’ll refer to them as the manipulated variables. These variables are manipulated by an actuator. An actuator is a generic term that refers to a device or motor that is responsible for controlling a system5 . Since the actuator is a physical device and is usually embedded within the process itself it can be useful to refer to the collection of both process and actuators as a single system that we’ll call the plant6 .

The actuators are driven by an actuating signal that is generated by the controller. The controller is designed specifically to convert a commanded variable - which comes from someone operating this device or from a higher level control system - into appropriate actuating signals. At this point we have our first, and simplest, 4 Or

if you lack creativity you could just call it the controlled system car’s engine and drive train are obvious actuators because they generate the force that manipulates the speed of the car (the process), but actuators can be less obvious as well like a voltage regulator in an electrical circuit 6 Other textbooks and online resources might use plant and process interchangeably so be aware of that when referring to them. In this book, however, I will stick to this definition. 5A

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control system. As the operators, we could now select a set of pre-determined commands that we play through our controller. This will generate the resulting actuator commands which in turn affect the manipulated variable which then affects the process in a way that we desire. This type of control system is referred to as open-loop since there is no feedback from the output of the process. Open-loop control systems are typically reserved for simple processes that have well defined input to output behaviors. A common household example of an openloop control system is a dishwasher. This is an open-loop system because once the user sets the wash timer the dishwasher will run for that set time. This is true regardless of whether the dishes are actually clean or not when it finishes running. If the dishes were clean to begin with the dishwasher would still run for the prescribed time and if you filled the dishwasher full of pots with baked on grime then the set time might not be enough to fully clean them and would have to be run again. We accept this inefficiency in the run time of the dishwasher because the starting process (the dirty plates that we want cleaned) is generally well known and therefore the time it takes to clean them is pretty consistent.

The manufacturers understand though that sometimes you will fill the dishwasher with grimy pots and want it to run for a longer period. Rather than build a complicated closed-loop system they have addressed this problem by adding additional pre-determined commands; that is they add multiple types of cleaning cycles that Revision 1.3

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run for different times and at different temperatures. Then it is up to the user to select the correct set of commands to get the desired effect. For any arbitrary process, though, an open-loop control system is typically not sufficient. This is because there are disturbances that affect your system that are random by nature and beyond your control. Additionally the process itself might have variations that you don’t expect or prepare for7 . Process variation and external disturbances will alter the behavior of your system - typically negatively - and an open-loop system will not be able to respond to them since it has no knowledge of the variation in the process output. So what can we do about this? We add feedback to our system! We accept the fact that disturbances and process variations are going to influence the controlled variable. However, instead of living with the resulting error we add a sensor that will measure the controlled variable and pass it along to our controller. Now we can compare the sensed variable with the commanded variable and generate an error term. The error term is a measure of how far off the process is from where you want it to be and the controller can use this to produce a suitable actuating signal which then produces a suitable manipulated variable which finally affects the process in such a way that it reduces the error term. The beauty of the feedback control system - or a closed-loop control system8 is that it is able to react to changes to the controlled variable automatically by constantly driving the error term to zero. 7 One

example of process variation is the change in electrical resistance over temperature. An open-loop control system that works at room temperature might not work when your process is extremely cold or hot due the variation in resistance throughout your electronics 8 The term closed-loop comes from the resulting loop that is formed in the block diagram when you feed back the controlled variable. Revision 1.3

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The feedback structure is very powerful and robust which makes it indispensable as a control tool. Unfortunately, with the addition of the feedback structure comes new problems that we now have to address. We need to think about accuracy of the controlled variable at steady state, the speed with which the system can respond to changes and reject disturbances, and the stability of the system as a whole. Also, we’ve added sensors which have noise and other inaccuracies that get injected into our loop and affect the performance. To counter this last problem we can add redundant sensors that measure different state variables, we filter them to reduce the noise, and then we blend them together to create a more accurate estimate of the true state. These are some of the tools we can employ as system designers and part of what we’ll cover in the rest of this book.

1.4

What is a control system?

From the first few sections you probably already have a vague understanding of what a control system is. You might be thinking that it is something that makes a system behave in an automated fashion or is something that allows a system to Revision 1.3

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operate without human intervention. This is true, to some degree, but the actual definition is broader than you might think. A control system is a mechanism that alters the behavior (or the future state) of a system.

Sounds like almost anything can be considered a control system, right? Well, one of the defining characteristics of a control system is that the future behavior of the system must tend towards a state that is desired. That means that, as the designer, you have to know what you want your system to do and then design your control system to generate that desired outcome. In some very rare cases the system naturally behaves the way you want it to and doesn’t require any special input from the designer. For example, if you want a system that keeps a ball at the bottom of a bowl there wouldn’t be a need for you to design a control system because the system performs that way naturally. When the ball is disturbed it will always roll back toward the bottom of the bowl on its own.

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However, if you wanted a system that keeps a ball at the top of an inverted bowl, then you would need to design a control system to accomplish that. This is because when the ball is disturbed it will not roll back to the center naturally but instead continue rolling off the side of the inverted bowl.

There are a number of different control systems that would work here. There is no right answer but let me propose a possible solution - even if it is quite fanciful and not very practical. Imagine a set of position detecting radar guns and wind generating fans that went around the rim of the bowl. As the ball deviated from the top of the bowl the fan closest to it would turn on and blow the ball back up to the top.

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The set of fans, radar guns, position estimators and control algorithms would count as a control system because together they are altering the behavior of the ball and inverted bowl dynamics. More importantly, however, they’re driving the ball toward the desired state - the top of the inverted bowl. If we considered each interconnected part as its own little system, then the block diagram of the entire feedback system would look something like this:

This is a very natural way to split up the project as well because it allows multiple control specialists to work together toward a common goal. Instead of everyone trying to develop all parts of a complicated control system, each person would be responsible for designing and testing their part. Someone would be responsible for selecting the appropriate radar gun and developing the ball position estimator algorithm. Another person would be responsible for building the fans and the electronics to run them. Finally, a third person would be responsible for developing the control algorithm and setting the system requirements for the fan and radar spe-

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cialists. Together these three ball balancing engineers would make up the control system team.

1.5

The First Feedback Control System

Feedback control systems exist in almost every technology in modern times, but there was a first feedback control system. Its story9 takes place in the 3rd century BC in Alexandria, Egypt - 2000 years before the Industrial Revolution, at a time when Euclid was laying out the principles of geometry and Archimedes was yelling "Eureka!" over discovering how the volume of displaced water could lead to the density of the object. Our protagonist is the Greek mathematician Ctesibius, inventor of the organ and widely regarded as the father of pneumatics due to his published work on the elasticity of air. We can overhear the conversation Ctesibius is having with one of his students, Heron, about an invention he has just completed - an invention that you will soon see is directly related to the Fundamentals of Control theory. CTESIBIUS: I have done it! HERON: What is that Master Ctesibius? CTESIBIUS: I have invented a mechanism - something rather ingenious I might add - that will allow anyone to know the time of day. 9 If

you’re not interested in a story you can skip this section without loss of continuity in the book ... but c’mon, it’s only a few pages and it’s an interesting tale of the ancient ingenuity that led to modern day control theory Revision 1.3

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HERON: But Master, we already have a number of ways of knowing the time. As you well know I can glance over at this sundial and see from the casted shadow that it is just past 11 in the morning. CTESIBIUS: That is true. The sundial is wonderfully simple and humans have been using it to tell time for at least 3000 years. But it has its problems. How can you tell the time at night, or if it is a cloudy day, or if you are inside a building? HERON: That’s easy! At those times we use our water clocks. We take a container that has a small spigot at the bottom and fill it with water. We let the water drain slowly through the spigot until it is empty. Since we know how long it takes to empty the container we then know how much time has passed.

CTESIBIUS: Hmm, that is once again true, but what you have described is a timer and not a clock. There is a difference and it is very important. A timer is a device for measuring how much time has elapsed over some interval, whereas a clock’s measurement is related back to the time of day. The sundial is a clock because

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we can see that it is 11am, but using your water container we only know that perhaps one hour has passed since we opened the spigot. HERON: Well, if we started the spigot at 11am then when it completes we know that it is noon. Then we just start the process over again to always know the time. CTESIBIUS: Exactly, that would make it a clock! But what if you wanted to know the time when the container was not yet empty? HERON: I guess we could see how full the container was by indicating the height of the water on the inside wall. Then if the container was three quarters full we would would say that one quarter of the time has elapsed.

CTESIBIUS: There is a problem with this method though. Can you see it? The water will drain from the spigot much faster when the water level is high and the flow will gradually slow down as it empties. Therefore, a three-quarter-filled container means that less than a quarter of the time has actually elapsed.

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I can tell that you are not convinced that this is a problem, right? You are going to tell me that the markings on the inside of the container don’t need to be uniformly spaced, or that the walls of the container could slope inward so that water level will drop at a uniform pace.

But this is hiding the real issue. By accepting that the flow rate through the spigot will change over time we need to have some extra knowledge - namely how to shape the inside of the container or where to mark the non-uniform indications on the inside wall. Once we create those markings or that container then we have no control over it. Any errors in manufacturing will generate errors in our results. What we really need is a spigot that will have a steady and continuous flow rate. That way we don’t rely on the container at all, we just need to know how much water comes out in an hour. From there, deriving any other time is as simple as measuring how much Revision 1.3

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water has been released and comparing it to the amount released in an hour. Do you have any ideas on how to accomplish a steady flow rate from the spigot? HERON: Let me think about it. The flow rate decreases because the water level drops in the container and the pressure exerted at the spigot is lower. So by keeping the water level in the container constant, the flow rate will be constant. Ah, but how do we keep the water level constant? I got it! I’ll modify the tank. It will have two spigots, a large one at the top and a smaller at the bottom. We’ll feed water into this container at a much faster rate than the smaller spigot can handle which will fill the container up. Once the water level reaches the larger spigot, it will begin to overflow, which will keep the water fixed at that height. Is this your invention Master Ctesibius?

CTESIBIUS: No, no, no! The overflow tank will accomplish a steady flow rate for sure but in solving our problem you’ve just introduced another one. Your clock will use and waste a lot of Revision 1.3

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water. This will cause you to need a larger water source reservoir and that will make your clock less mobile. There is an elegant solution to this problem, and that is what I’ve just discovered. We still have the same container from before, but it is fed by a continuous water supply with a valve with a circular opening. We place a float in the shape of an inverted cone in the water container just below the water source inlet.

When the water level is high the float is pushed up into the valve such that it shuts off the water supply. As the container water level decreases, the float drops, allowing the supply water to flow. The water level will reach a steady state once the float is low enough that the water flowing in is exactly equal to the water leaving the spigot. The beauty of this is that it is self correcting! If for some unforeseen reason the water level drops in the container, the float drops with it causing more water to be supplied to the container than it is losing through the spigot. This has the benefit of filling the container back up. It’s brilliant!

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Now we can add a larger container to catch the falling water and place a second float in there to mark the hour of the day. We only need as much water as it takes to fill the two containers in order to know the time all day. No wasted water!

HERON: That is brilliant! I bet there are many different applications where we could use this float regulator. CTESIBIUS: Absolutely. Oh, is it really almost 12pm? I have to run, I’m needed at the Museum of Alexandria. Think of those other uses for this invention. I’d love to hear what you come up with. With 2300 years of technological advancements to base your opinion on, this cone shaped float might not seem like much but the float regulator would go on to be used for many applications - in fact it’s the same technology that is still used in modern day toilets. The real benefit of feedback control systems is that the system is self correcting. Now that systems could automatically adjust to the changing environment it removed the need for people to be part of the machine operation. This is similar to cruise control on your car removing you as the controller of your

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speed. This is the goal of a control system engineer - through ingenious design and application develop systems that can regulate an output automatically. However, as you will see this opens a series of challenging and exciting problems. It will take mathematics to expose these problems and so now that we have the context of the problem we’re trying to solve let’s move onto the next chapter and discuss how we represent the problem mathematically.

1.6

Try This! 1. Come up with another possible control system for the inverted bowl problem.

a) What does your system use for sensors? Actuators? b) Explain some of the benefits and drawbacks of your design? Consider things like power usage, sound volume, ease of assembly, ability to scale to larger systems, and coolness factor. c) Make a sketch of your control system and point out how you would split up the project so that multiple people could work on it. d) Share and discuss your ideas with the world and see what other students have created by going to http://bit.ly/inverted_bowl.

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2. What additional applications are there for the float regulator? These can be problems that have been solved by a float regulator and those that could be solved by them. 3. How do humans act as the control system and how do they ‘close the loop’ with machines? As an example think about what a person is doing when they’re driving a car. 4. Find examples of control systems in your everyday life (closed loop, open loop). Control systems don’t always need to be machines, think about how feedback control is part of your relationships, your approach to studying for an exam, or the cycle of being hungry and eating. 5. Describe each of the following control systems. Determine the inputs, outputs and process. Describe whether it is open-loop or closed-loop. a) Your home air conditioning system b) Sprinkler system for your lawn c) The lighting in a room d) The fly-by-wire system on an aircraft e) The population of a colony in an area with limited resources

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Chapter Credits

Meg Douglas Federico Pistono

Snohomish, Washington

Benjamin Martin

1 AU

Wong, C.J.

Dubai, UAE Zootopia

Thanks for making this chapter awesome!

29

2 Transfer Functions

As an engineer it is crucial that you are able to describe your system in an efficient and useful manner. What is efficient and useful, however, changes depending on the context of your problem. For example, the first chapter explained systems conceptually so they were depicted with drawings illustrating the collection of parts that make them up. The drawings were also complemented with descriptive words to help you understand what the drawings represented. If, however, your problem is to build a controller that alters the behavior of your system then words and pictures are no longer the most efficient and useful way to represent your system. For example, imagine you were given the following description of a restrained cart and asked to describe how the cart moves if a force of 1 Newton is applied for 1 second.

You could probably reason through this problem by imagining that while the force is applied the cart will begin to accelerate in the direction of the force - faster at first but slowing as the restorative force from the spring grows. Once the applied force is removed the cart will spring back toward its resting state. The damper will remove energy from the system, and depending on its relative strength, will either cause the cart to oscillate with a shrinking amplitude or will cause the cart to asymptotically return to its starting position. 30

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Not a bad description - but if you were tasked with developing a system that automatically adjusted the applied force so that the cart followed a desired profile then this description of the system would not be sufficient. So what can we do? We describe the system mathematically. We do this by writing the equations of motion in the form of differential equations. From the description of the problem the equations of motion can be written directly using a free-body diagram. The mass, spring constant, or damping coefficient were not specified so we can make them variables, m, k, and b, respectively1 .

At this point we are left with a single 2nd order ordinary differential equation, mx(t) ¨ + bx(t) ˙ + kx(t) − Finput (t) = 0. We call this the mathematical model of the system. The external input, or the excitation, into our model is the force applied to the cart, Finput , and when we solve the differential equation we get the position of the cart over time, x(t).

1 It’s

important to remember that most of the time when you are trying to solve the control problem you also have to solve the system identification problem and the simulation problem as well. Writing out the equations of motion is part of system identification and is the white box method that was introduced in the first chapter. Beyond this, however, finding the appropriate m, k, and b requires testing of your system and this is part of the black box method. Revision 1.3

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A differential equation is great for solving for the response of a system but it doesn’t lend itself very well to analysis and manipulation, and this is something that we absolutely want to do as control engineers. The whole point is to analyze how the system naturally behaves and then manipulate it so it behaves the way we want it to. Luckily there are other ways to represent a mathematical model which makes the control engineer’s job easier. The two most popular representations, and the two that we’ll cover in depth in this book, are state space representation and transfer functions. Loosely speaking, transfer functions are a Laplace domain representation of your system and they are commonly associated with the era of control techniques labelled classical control theory. State space is a time domain representation, packaged in matrix form, and they are commonly associated with the era labelled modern control theory.

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Each representation has its own set of benefits and drawbacks and as a control engineer you will need to be very familiar with both. Don’t get too hung up on the labels classical and modern. In this book, we won’t separate classical control and modern control into two separate sections. Rather, we will derive techniques and solve problems using whichever method is most appropriate. This way you will become comfortable switching between representations, and therefore switching between the set of tools that you can use as the problem requires. In this chapter we will focus on transfer functions and so to begin let’s start with the formal definition. A transfer function is the Laplace transform of the impulse response of a linear, time-invariant system with a single input and single output when you set the initial conditions to zero. They allow us to connect several systems in series by performing convolution through simple multiplication. Yikes, that was a lot to take in! Don’t worry if that didn’t make any sense. Transfer functions are too important in control theory to gloss over quickly so we’ll walk through each of those terms very carefully and explicitly. That way not only will you have a good idea of how to use transfer functions but you’ll learn why and when to use them as well. Revision 1.3

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Before we jump into explaining the definition of a transfer function let’s set up an example where representing our system as transfer functions make the control engineer’s job easier. Let’s take the inverted bowl control problem from the first chapter. Before a control system can be designed that will keep the ball on top of the inverted bowl, we first need to understand the behavior of the entire system. That means when we apply a command to the fan we want to know how that affects the estimated ball position.

Let’s say we apply a step command to the fan - for example to go from off to half of its max speed2 . There is a delay as the fan has to accelerate over some time period to get to speed and after which there is some variation in fan speed due to physical disturbances in the system. The output of the fan system is air velocity which is subsequently the input into the inverted bowl dynamics. The bowl dynamics system calculates the force on the ball from the air and uses that force to determine how the ball moves. The true ball position is then sent to the radar sensor model which produces a relative distance to the radar gun. Just like the fan, the radar system introduces more delay and it also adds errors in the measurement. The relative ball position is then used to estimate where the ball is in the bowl frame which is the final output of our system. 2 You

do this whenever you turn on a house fan to medium

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We could write out the differential equation for the entire end-to-end system which relates the fan command to the estimated ball position, but this would be difficult to do because of how complex each of the parts are individually. Also, recall that we separated the system into smaller, more manageable parts, so that we could have several engineer’s working simultaneously on the problem. Therefore, what would be ideal is a way to represent each part separately and then combine them into a full system later. This would allow each engineer to write out a simpler mathematical model of their own part and supply it to the person responsible for pulling the model together and designing the control system for it. So with this example in mind let’s walk through the explanation of transfer functions and see why they are the perfect representation for our problem.

2.1

LTI Systems

According to our formal definition, transfer functions require that you have a linear and time-invariant (LTI) system. To understand why this is the case we need to learn what an LTI system is and review a small amount of linear theory. When you model your system you get to choose the set of mathematical operations that map the system inputs to the outputs. This is a fancy way of saying that you get to derive the differential equations that represent the behavior of your system and since you are in charge of your model you can decide what to represent and how complex your representation is. You have dozens of mathematical operations at your disposal, however, I’m going to make a case for representing the system as linear, time-invariant, in which case you actually can choose only from a few mathematical operations. There are so few in fact that we can easily list every one of them.

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If you can model your system with some combination of these six operations, and only these six operations, then you can make assertions about how the output of the system will change based on changes to the input. This is because all LTI systems have the following properties; homogeneity, superposition, and time-invariance. These properties are what cause the system to behave in predictable ways. To understand what these properties mean let’s walk through them one at a time. For these examples I’m going to represent a collection of linear operations with the linear operator, h. With this notation, y(t) = h(x(t)), can be read as the operator, h, provides a linear mapping between the vector x(t) and the vector y(t).

Homogeneity means that if you scale the input, x(t), by factor, a, then the output, y(t), will also be scaled by a. So in the example below, a step input of height A produces an oscillating step to height B. Since h(x) is a linear system then a step input that is doubled to 2A will produce an output that is exactly doubled as well.

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Superposition, or you might also hear it called additivity, means that if you sum two separate inputs together the response through a linear system will be the summed outputs of each individual input. In the example below the step input, A, produces output, a, and the ramp input, B, produces output, b. Superposition states that if we sum inputs A + B then the resulting output is the sum a + b.

We can describe these properties formally as:

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Or more generally, and if you make the substitution that y(t) = h(x(t)), we can combine homogeneity and superposition into one large definition.

A system is defined as a linear system if it has the two properties homogeneity and superposition. Side note: Don’t mistake a linear system and a linear equation. They are two separate things. We’ve just described a linear system, it is a mapping between two vector spaces that obeys the properties of homogeneity and superposition. A linear equation, on the other hand, is an algebraic expression where every term is a single, first-power variable multiplied by a constant. A well known example of a linear equation is the equation of a line in a two dimensional plane, y = mx + b. You can verify that this equation is not homogenous because, for example, the output is not doubled when you double the input, 2(mx + b) , m(2x) + b.

Linearity is only the first part of an LTI system. The second part, time invariance, refers to a system behaving the same regardless of when in time the action takes place. Given y(t) = h(x(t)), if we shift the input, x(t), by a fixed time, T , then the output, y(t), is also shifted by that fixed time. We can write this as y(t − T ) = h(x(t − T )). Sometimes this is also referred to as translation invariance which covers translation through space as well as time. Here’s an example of how shifting an input results in a shifted output in a time-invariant system.

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The restrictions required by an LTI system are severe3 , so severe in fact that no real physical system meets them. There is always some aspect of non-linearity or variation over time in the real world.

So you might be thinking, "great, we know how we can scale, shift, and sum inputs into an LTI system, but if they don’t represent real systems then why are they so important and how does it help us understand transfer functions?" To answer your first question I think theoretical physicist, Richard Feynman, said it best when he said "Linear systems are important because we can solve them." We have an entire arsenal of mathematical tools that are capable of solving LTI systems and, alternatively, we can only solve very simple and contrived non-LTI systems. Even though no real system is LTI there are, however, a wide range of real problems can be approximated very accurately with an LTI model. As long as 3 We

only get to choose from 6 operations?! That’s like restricting Van Gogh to just the color brown!

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your system behaves linearly over some region of operation, then you can treat it as LTI over the region. You can create a linear model from a non-linear equation through a process called linearization which is a skill that we’ll cover in a later chapter. To answer your second question, we know that the definition of transfer functions requires that the system be LTI, but we haven’t gotten to why. To answer that question we need to talk about the impulse function.

2.2

Impulse Function

An LTI system can be fully characterized by knowing how the system behaves when an impulse is applied to it. The resulting output of a system that is subjected to an impulse function is called the impulse response of the system. You probably already have a general idea of what an impulse is4 , but just to be clear let’s define it here. The impulse function is a signal that is infinitesimally short in time but has infinite magnitude. It is also referred to as the Dirac Delta function, which is named for Paul Dirac, the theoretical physicist who first introduced the concept. I’ll use the terms impulse function and Dirac Delta function interchangeably throughout this book. Since it is impossible to draw a line that is infinitesimally thin and infinitely tall we represent a Dirac Delta function as an arrow pointing up at the time the impulse is applied.

4 An

impulse is that sudden and strong urge to buy a snack in the checkout line at the grocery store

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You can also represent this mathematically by stating that the function returns a value of positive infinity at time zero and returns a value of zero at all other times. Additionally, the impulse function is defined such that the integral of the function is one. Or to put it differently, even though the function is infinitesimally thin, and therefore has no thickness and so no area, when we perform an integration on the function we say that it actually does have area and define that area to be one unit.

Being able to integrate the Dirac Delta function is crucial because we can assign it to physical properties and perform mathematical operations on those properties like we would with real finite functions. For example, the impulse could represent the force you exert on a 1kg mass.

We know that acceleration is force divided by mass. Therefore, if the force was infinite we’d find the object would experience infinite acceleration - not a useful result. However, if we integrate the acceleration over time we get the object’s velocity. Using the definition of the integral of the impulse function we find that Revision 1.3

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the mass accelerates instantly to 1 m/s - and this is a useful result. We can use the impulse function to change the state of the system in zero time; or in this case we were able to mathematically give the mass an initial velocity of 1 m/s. Let’s walk through a thought exercise using the impulse function and see if we can start to tie this back to LTI systems and eventually back to transfer functions. Imagine you have a block sitting on a table and you hit it with a hammer. This would be very close to an impulse because the hammer would apply a very large force to the block over a very short period of time. This would give the block an instantaneous initial velocity and start it sliding across the table. The block would then slow down over some amount of time due to friction and would eventually stop. The resulting change in velocity over time is the impulse response of the system.

Here is our system drawn out in block diagram form so you get a better idea of the input to output relationship.

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We still call it the impulse response regardless of whether we treat this system as LTI or not5 , however, for the sake of this thought exercise we’ll say that our system behaves like an LTI system so that we can take advantage of the LTI properties of homogeneity, superposition, and time invariance. To continue, let’s say that after the mass came to rest we hit it again with the hammer but this time half as hard. Since this system is time invariant we know that if we shift the impulse by time T then the impulse response is also shifted by T. Additionally, because the system obeys homogeneity, if we scale the input by one half then the output will also be scaled by one half. Finally, due to superposition we know the motion of the block is the summation of the first impulse response and the second impulse response.

We can see the power of summing the impulse responses of an LTI system by striking the block multiple times in quick succession.

5 Non-LTI

systems still respond to impulses, we just can’t infer as much about the system from the impulse response as we can with LTI systems. Revision 1.3

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If the input into our system is a series of impulse functions then we know how to sum the individual responses to create the total response of the system. This brings up the question: what if our input isn’t an impulse function? Is there something we can claim about the response to any arbitrary input if we know the impulse response?

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concepts that can’t physically happen. Therefore, let’s see how we extend our summing technique to real continuous inputs using the convolution integral.

2.3

Convolution Integral

The convolution integral is a mathematical operation that you perform on two functions - we’ll call them f (t) and g(t) - and it is written in shorthand notation as an asterisk or a star. Since the convolution integral resides in the mathematical domain a lot of effort is spent solving the integral for a number of unique and interesting input functions. However, being able to solve the integral usually does not help the student understand what the convolution integral is doing or why it works in the first place. Hopefully, by walking through how it relates to ‘playing’ arbitrary inputs through an LTI system this chapter can make convolution a little less convoluted6 .

The convolution integral might look daunting at first, but there are really only three parts to the equation; (1) you reverse the input function g(t) and shift through all of time, (2) you multiply the reversed and shifted g(t) by f (t), and (3) you sum the product over all of time. You can picture this graphically by taking a time history of g(t), drawing it backwards, and sliding it across f (t). The value of the output function is the area under the two input functions when they overlap. 6 See

what I did there?

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This isn’t a bad visual explanation of the convolution integral, but it still doesn’t explain why this produces a function that means anything. So let’s answer that by deriving the integral from scratch. We’ll accomplish that by solving the problem we started with: how to play arbitrary inputs, f (t), into an LTI system and determine the response.

Let’s magnify f (t) and just look at the very beginning of the function. In fact, we’ll just look at the first infinitesimally thin slice of the input function, dτ. The area under the curve for this brief portion can be approximated as f (dτ) · dτ, or in words, the height of the function times the width of the slice.

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This assumes that f (t) is constant for the entire slice of dτ, hence it’s an approximation. However, if we take the limit as dτ → 0 then this becomes the exact area under that instant of the curve and if we sum each dτ over all time then we get the area under the entire curve7 . More about taking the limit later, for now we’ll just assume dτ has thickness and this process is just an approximation. Since we have the area under this slice we can replace just this small section of f (t) with a single scaled impulse function. The impulse function has an area of 1 so if we multiply it by the area under our slice we’ve essentially scaled the impulse function to have a similar area.

This is great because we know what the response will be from this small slice of the input function - it will be the impulse response scaled in the exact same way. 7 You’ll

notice we just described standard integration of a function

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We can make this assertion since this is an LTI system and, through homogeneity, scaling the input produces a similarly scaled output.

If we plot the system’s response to just this first scaled impulse then it would look like the graph below on the left. Notice, however, if dτ is extremely small then the impulse response will be scaled way down and you wouldn’t even notice its impact.

But don’t worry! We will move onto the second dτ slice and you’ll start to see a pattern building.

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Each time you move to the next dτ you replace it with a scaled impulse function. This produces a scaled impulse response that is shifted in time to correspond to when the impulse function occurred. This shift in time is permitted because, again, our system is LTI and therefore time invariant. Also, each individual impulse response - which has been scaled down to almost nothing - is summed together using the property of superposition. As you move along the input function you are creating layer upon layer of infinitesimally small impulse responses that build on each other.

We can proceed through each of these discrete dτ steps until we get through the entire input function. We can write this in a compact form using the summation operation and stepping through an infinite number of i steps. This is discrete convolution and it is how computers perform the operation. Remember this is an Revision 1.3

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approximation - we have to take the limit as dτ → 0 for it to be exact. When we do this each discrete step is replaced with a continuous operation and the summation operator becomes the integral operator.

This is the continuous time convolution integral function that we started with with one small difference; the integration limits go from zero to infinity in our example and negative infinity to infinity in the original function. This is one of the differences between a pure mathematical function and one that is used in practical applications. In engineering, often our signals start at time zero and since there is no signal between negative infinity and zero we don’t bother performing the integration over that region. However, you’ll end up with the same answer regardless of whether the lower bound is negative infinity or zero.

An interesting observation: Multiplying two polynomials together can be accomplished by performing the discrete convolution of the polynomial coefficients. To understand this let’s look at how you would approach multiplying two, two-term polynomials, using the popular, but ultimately limiting FOIL method.

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I say this is limiting because this rule of thumb breaks down for multiplication involving a polynomial with more than two terms.

Therefore, if you realize that polynomial multiplication is really no different than regular multiplication you’ll notice that all you are doing is multiplying every term with every other term and summing like units. This example multiplies x2 + 2x + 3 and 3x2 + 1.

This is exactly what discrete convolution is doing. We can define the first polynomial as the vector [1, 2, 3] and the second polynomial as the vector [3, 0, 1]. To perform discrete convolution we reverse the order of one of the vectors, sweep it across the other vector, and sum the product of the two.

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In fact, with the program MATLAB, you can perform polynomial multiplication using conv, the command for discrete convolution. f = [1 2 3]; g = [3 0 1]; w = conv(f,g)

w = 3 6 10 2 3 This corresponds to the polynomial 3x4 + 6x3 + 10x2 + 2x + 3. Convolution gives us the ability to determine an LTI system’s response to any arbitrary input as long as we know the impulse response of the system. Going back to our inverted bowl problem we now have a way of stepping our fan commands through each separate system in order to determine how the total system behaves. We would first convolve8 the fan commands with the impulse response of the fan. The output would be the air velocity which we would then convolve with the impulse response of the inverted bowl system. That output would be the true ball position that we would convolve with the radar sensor impulse response to generate the measured ball’s position. Finally, we’d convolve that output with the 8 Yes,

the verb is convolve. It’s not convolute, convolt, or convolutionize.

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estimator impulse response to give us the estimated position that results from the initial fan commands.

We’ve successfully played our commands through the entire system but perhaps you see a problem with this method. Namely, the convolution integral seems pretty messy and preforming that integration for arbitrary inputs would be overly cumbersome. You are correct, it is no fun! Not only is it difficult to perform the integration but convolution doesn’t allow us to easily combine several systems into a single large system. For example, if we wanted to produce the differential equations that relate the fan commands directly to the estimated ball position without having to go through each step along the way then convolution isn’t going to help us. What will help us? You guessed it, transfer functions. We can perform convolution with transfer functions as well, but the good news is that we do that using multiplication rather than integration. In order to continue on our journey to the transfer function we need to leave the comfort of the time domain and venture out into the frequency domain.

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2.4

The Frequency Domain and the Fourier Transform

In this section we will cover a brief introduction to the frequency domain and the Fourier Transform. I say it’s brief because a full treatment of the material would be a whole book on its own. The goal of this section, however, is not to fully understand the math involved in getting to and from the frequency domain but rather to provide just enough information to grasp its importance to transfer functions and to understand why the frequency domain makes our lives easier as control engineers. At first glance going to the frequency domain will seem like an inconvenient step but as you will learn, and practice throughout this book, it will be well worth the effort. It’s easy to understand the physical meaning of time domain equations because we experience life in the time domain. You have probably worked with equations that had, for example, parameters that changed as a function of time. Distance = velocity ∗ time is a well known kinematic equation that describes an object’s motion while moving at a constant velocity. Think back to when you were traveling somewhere - for example walking to your friend’s house. Perhaps after 10 minutes you were a fourth of the way there so you do some quick mental math and predict that it will take you about 30 more minutes to get to their house. Plotting the journey through time on one axis and the journey through space on another axis produces your motion as a function of time, f (t).

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It makes sense to think of this type of equation in the time domain and it’s a little comforting to be able to relate the result back to a physical experience. However, let’s move past the walking example and imagine a mass sitting on top of a spring. If we applied an impulse force to the mass it would start to bounce up and down like a jack-in-the-box. If there was no damping in the system, or no loss of energy in any way9 then the mass would continue to bounce up and down forever.

Forever is pretty hard to graph in the time domain, but more importantly it can be difficult in some situations to observe meaningful behavior when you only see a system’s time response.

For this particular system we can fully characterize the response by defining just three parameters; the frequency of the bouncing, the amplitude of the bouncing, 9 We

can write an equation for a system that doesn’t lose energy but just like a linear system this can’t physically happen. In real life there is always loss of energy - usually from friction which generates heat which then leaves the system through convection, conduction, and radiation. Revision 1.3

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and the phase shift corresponding to the starting position of the mass. We can see this clearly by deriving the time domain equations of motion for the system.

From here we can solve the differential equation, mx(t) ¨ + kx(t) = f (t), by assuming the solution is in the form x(t) = Acos(ωt + φ ) and then solving for the three unknown coefficients, A, ω, and φ . Since there are three unknowns we need three equations to solve for them. For the first equation we can calculate the 2nd derivative of x(t) and then with x(t) plug them into our equation of motion.

The last two equations come from the two known initial conditions. We know the initial position is at rest resulting in x(0) = 0. We also know from earlier that the impulse force generates instantaneous velocity equal to 1 divided by the mass of the object which gives us x(0) ˙ = −1/m. It’s negative since the force is applied in the negative direction.

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Since we’re accounting for the input force as an initial velocity we set the force to zero in the first equation. At this point a little algebra gives us the frequency of q the bouncing, ω =

k m,

the initial starting point for the bouncing, φ = π2 , and the

amplitude of the bouncing, A =

√1 . km

We’ve just shown that the motion of q the block is described in the time domain by a

simple cosine wave, x(t) = √1 cos( mk t + π2 ), and if we wanted to plot this in the km time domain then we’d need an infinite amount of paper. However, to recreate a cosine wave we only need to know its frequency, amplitude, and phase and we can plot that information easily using two separate graphs; one for amplitude and one for phase. When we start thinking about a signal in terms of frequency, amplitude and phase we’ve moved out of the time domain and into the frequency domain. That is we are thinking of a signal in terms of the characteristics of the frequencies that make it up rather than how it changes over time.

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You can really see the benefit of viewing a signal in the frequency domain when your solution is made up of more than one cosine wave. In the time domain the signal could look random and chaotic, but in the frequency domain it is represented very cleanly.

It’s important to realize that we aren’t losing any information when we represent a signal in the frequency domain, we’re just relating the exact same information in a different format. If our time domain equation is just a series of cosine waveforms, as the previous example was, then it’s easy to see how you could transform that equation to the frequency domain - just pick out the three parameters for each cosine and plot them. However, it is not always the case that a time domain signal is written as the Revision 1.3

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sum of a set of cosine waves. In fact, it is more often not the case. For example an extremely simple, non-cosine, time domain function is 0 for t < 0 and 1 for t ≥ 0.

Even though this looks decidedly nothing like a cosine wave we can still represent this step function in the frequency domain - that is we can convert it into an infinite number of cosines, each at a different frequency and with a different amplitude and phase. This conversion is done using a very powerful tool called the Fourier transform. A transform is a mapping between two sets of data, or domains, and the Fourier transform maps a continuous signal in the time domain to its continuous frequency domain representation. We can use a similar transform, the inverse Fourier transform, to map from the frequency domain back to the time domain10 .

The Fourier transform looks complicated but I assure you that it makes sense as a whole if you spend a little time deciphering each of its parts. Having said that, we’re not going to spend that time in this chapter! Instead I’m asking you to believe that it really does map a signal from the time domain to the frequency domain and back again11 . That means that if you have an equation as a function 10 Great,

more integrals! you are interested in a deeper understanding of the transform there is will be a short explanation in Appendix B 11 If

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of time and perform the Fourier transform integral the result will be a signal as a function of frequency and the values will be related to amplitudes and phases.

At this point, you might be thinking ‘the step function above is represented cleanly in the time domain and since it’s made up of an infinite number of cosine waves it’s much more complicated in the frequency domain.’ That’s true, but remember the problem we’re trying to simplify in this chapter is how to represent a system in a way that allows us to easily manipulate it and analyze it, not necessarily how to simplify plotting it. We got to the concept of convolution in the last section but got stuck because we realized that it is a difficult integral for any generic signal. Also, convolution doesn’t provide a simple way of combining several systems together to create a single equation for the larger system. To see how the frequency domain helps us simplify our problem let’s consider the following chart.

We know that the Fourier transform maps functions f (t) and g(t) to F(ω) and G(ω), respectively, where f (t) might represent an input signal and g(t) might Revision 1.3

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represent the system’s impulse response. In the time domain we can convolve the two to get the system’s response to input f (t), but how can we manipulate F(ω) and G(ω) in the frequency domain to produce a similar result? Or another way of putting it, what is the Fourier transform of ( f ∗ g)(t)? I think you’ll find the simplicity of it quite amazing.

2.5

Convolution versus Multiplication

In this section we are going to prove the convolution theorem which states that the Fourier transform of convolution is just the multiplication of the individual Fourier transforms. To prove this we are going to walk through the Fourier transform of the convolution integral12 . You’ll probably never have to prove this outside of a homework assignment or exam question, however, walking through it at least once is important because it forces us to dedicate several pages and a little bit of time to this topic and hopefully it will help you to remember the concept. Every single time you multiply two transfer functions you are taking advantage of the convolution theorem and remembering that will give you a better intuition as to what multiplication is actually accomplishing. To start the convolution theorem proof, let’s remind ourselves of the convolution integral and the Fourier transform.

To take the Fourier transform of the convolution integral we just replace f (t) with ( f ∗ g)(t), which of course is the convolution integral itself. The fancy F just denotes that we are taking the Fourier transform of what’s inside the parentheses. 12 Warning!

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This looks rather complicated but lets begin to pick away at it and see how it can be simplified. The first thing we do is rearrange the order of the integral. Right now we perform the summation of the inner integral with respect to τ and then do the outer integral with respect to t. A double integral can be integrated in either order as long as you are careful to transform the limits of integration appropriately. Luckily, our limits are both from −∞ to ∞ so rearranging the integrals is just a matter of pulling e− jωt dt in and pulling dτ out.

At this point we can move f (τ) out of the inner integral because it is just a function of τ and therefore a constant when integrated with respect to t.

There is something special about the equation inside of the square brackets - it can replaced with e− jωτ G(ω). To prove this we need to take a step back and talk about the Fourier transform shift theorem first.

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The Fourier transform shift theorem The image on the left shows the Fourier transform of an arbitrary function, f (t). The image on the right shows that same function shifted or delayed by time, τ. The question we want answered is what is the Fourier transform of that shifted function? We start by replacing f (t) with f (t − τ).

Then to get the time aligned to the same frame within the integral we can multiply the function by 1 (so we don’t change anything) but represent 1 as e− jωτ e jωτ . Since these exponentials are a function of τ, and therefore constant with respect to t, we can put them inside of the integral.

We can pull e− jωτ out of the integrala and combine the two remaining exponentials into e− jω(t−τ) .

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This little bit of mathematical trickery has resulted in both functions inside of the integral to be functions of the same time frame, that is they are both functions of t − τ. We can replace our time frame with T and adjust the integral limits accordingly. However, since we’re integrating over all time, a function that is shifted by a finite value has no impact on the integration limits. You’ll notice that what we are left with is just the standard Fourier transform.

So this is very interesting, the Fourier transform of a shifted function is just the Fourier transform of the original function multiplied by a constant related to the length of time of the shift, e− jωτ .

a We

didn’t really need to put it in there in the first place but I find the extra step makes more sense

Using our new found knowledge of the Fourier shift theorem we can plainly see that the function inside of the square brackets is really just the Fourier transform of g(t − τ), or the delay constant e− jωτ times G(ω).

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Since G(ω) is a constant with respect to τ we can pull it out of the integral, and what we are left with is the Fourier transform of f (t).

So after all of that we can safely conclude that the Fourier transform of the convolution integral really is just the multiplication of the individual Fourier transforms.

We’re not at the definition of the transfer function just yet, but keep in mind what we’ve just shown here. When you’re working in the frequency domain and you multiply two functions you are really accomplishing the same result as convolution in the time domain. So if you have a frequency domain representation of your system’s impulse response and arbitrary input signal then you can calculate the system’s response to that input by multiplying the two. Revision 1.3

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Transfer functions are not represented entirely in the frequency domain, however. They are in a higher order domain called the s domain where one dimension is in fact frequency, but the second dimension is exponential growth and decay. I know, this sounds crazy, but just like everything we’ve covered so far it is quite interesting and intuitive when you really understand it. So let’s continue on!

2.6

The s domain and the Laplace Transform

With each section of this chapter we’re drawing ever closer to understanding the transfer function, but this section is the most important yet. If up to this point you’ve just been quickly glossing through the chapter - hoping to absorb the information as fast as possible so you can go back to doing something fun - I encourage you to slow down now and really try to understand this section. There are many system analysis and control techniques that you will be exposed to that use transfer functions as the method for representing the system. Therefore, you will do yourself a huge favor by spending some time to fully grasp the Laplace transform and the s domain. Once you understand these two concepts, everything else involving transfer functions in the future will be much easier to learn and apply. 2.6.1

Remember the Fourier Transform!

In the last section we took for granted that the Fourier transform maps a signal in the time domain to the frequency domain and I alluded to the fact that the signal in the frequency domain has two parts; one part that is related to the amplitude of the resulting cosine waves and another part that is related to their phase. We can plot each of those parts on their own separate graph where the x-axis is the frequency of the cosine waves and the y-axis is the magnitude and phase, respectively. Let’s show a quick example starting from a time domain function and ending with the two plots, magnitude and phase, in the frequency domain. The time domain function we’ll use is a simple exponential decay, e−t . However, we want the signal Revision 1.3

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to be zero for all values of t < 0 so we’ll multiply it by a step function, u(t). This produces a function whose value is zero for negative time and whose value is 1 starting at t = 0 and then decays exponentially for positive time.

We can solve the Fourier transform for f (t) = u(t)e−t , however, since this is a common time domain function we can simply look up its frequency domain representation in a Fourier transform table13 . From any Fourier transform pair table online you can find it to be 1+1jω . Since this is a complex function it is made up of two dimensional numbers that have real and imaginary components. We can rewrite this function to separate out those two parts.

13 You

are more than welcome to solve the Fourier transform integration to prove this to yourself - it’s a good exercise - but for the purpose of writing transfer functions you’ll find that for both Fourier transforms and Laplace transforms you’ll more often than not just memorize the common ones or look up the conversion in a table. I’m not necessarily condoning this laziness, I’m just stating this is usually the case from my experience in engineering. Revision 1.3

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At this point, calculating the magnitude and phase is a matter of converting the rectangular coordinate representation, which are the real and imaginary parts, to polar coordinate representation14 .

What we did is take a one dimensional time domain function, u(t)e−t , and turn it into a two dimensional frequency domain function. In the time domain, the single dimension is the value of the function across all time. In the frequency domain the two dimensions are the real and imaginary components which, through some additional algebra, are the magnitude and phase of the cosine waves that make up the original time domain function.

14 This

might be confusing for this particular revision of the book because I haven’t written the appendix covering the mechanics of the Fourier transform yet. However, a better explanation will be provided in that section in a future release of the book. Revision 1.3

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The two graphs that are created in the frequency domain are a function of ω. In other words, the value of ω tells us where on the frequency line we are. The idea that the value of ω is a location on the frequency line seems like a really simple concept for me to state in this section, but keep it in mind as we move on to the s plane.

2.6.2

The s Plane

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signal into both cosines and exponential functions. So you can imagine that for the Laplace transform we need a symbol that represents more than just frequency, ω, it needs to also account for the exponential aspect of the signal. This is where the variable s comes in. s is a complex number, which means that it contains values for two dimensions; one dimension that describes the frequency of a cosine wave and the second dimension that describes the exponential term. It is defined as s = σ + jω. Let’s step back a bit and explain this in more detail. Exponential functions that have imaginary exponents, such as e j2t , produce two dimensional sinusoids through Euler’s formula15 , e jωt = cos(ωt)+ j sin(ωt). We’ve already seen how the variable ω is the frequency of the sine and cosine waves as well as describing the location on the ω line. For exponentials functions that have real numbers for exponents, negative real numbers give us exponentially decaying signals and positive real numbers give us exponentially growing signals. Two examples are e2t , which grows exponentially for all positive time, and e−5t , which decays exponentially for all positive time.

15 Once

again sorry for any confusion right now. The appendix on the Fourier transform will cover Euler’s formula in more detail. For now the important thing to know is that raising an exponent to an imaginary number produces cosine-like waves rather than a function that grows or decays exponentially. Revision 1.3

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We can replace the real number in the exponent with the variable σ to give us f (σ ) = eσt . Just like with ω, σ gives us a way to define a location on a real number line that corresponds to a particular exponential function. As you move away from the origin, the absolute value of the real number becomes larger and thus the signal decays or grows at a faster rate.

Now let’s think about our new variable s which has both a real and imaginary component. Therefore, the equation est is really just an exponential function multiplied by a sinusoid, est = e(σ + jω)t = eσt e jωt .

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It would be cumbersome to have two separate number lines to describe s; one for frequency and one for the exponential rate. Therefore, instead we combine them into a two dimensional plane where the real axis is the exponential line and the imaginary axis is the frequency line. The value of s provides a location in this plane and describes the resulting signal, est , as function of the selected ω and σ .

2.6.3

The Laplace Transform

With our new found knowledge of the variable s and how the function est produces a signal that has both an exponential and sinusoidal component, we can now move on to describing the Laplace transform. An intuitive way to understand the Laplace transform is by contrasting it with the Fourier transform. Mathematically the two are exceedingly similar and this can lead you to believe that we use their result in the same way. You’ll soon see that this is not the case.

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Obviously the difference is that we’ve replaced jw with s. However, since s = σ + jω, rather than replacing jw what we are actually doing is adding the real component, σ , to the equation. If we expand s in the Laplace transform and rearrange the equation something interesting emerges. We find that our original time domain function f (t) is first multiplied by an exponential term e−σt and then we end up taking the Fourier transform of the product f (t)e−σt .

What does that mean and why is it interesting? Well, this gives us a way to interpret the Laplace transform graphically. Revision 1.3

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Let’s refer back to the s plane and look at the imaginary axis. This is the line where σ = 0.

Since σ = 0, the Laplace transform for values of s along this line is exactly equal to the Fourier transform.

Remember that the results of the Fourier transform are a set of two dimensional numbers that represent magnitude and phase for a given frequency. The results of the Laplace transform are still the same two dimensional numbers, but now we plot them on a 3-dimensional s plane rather than just the along the frequency line.

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The Region of Convergence I will accidentally mislead you if I don’t clarify a statement I made. I stated that the Laplace transform is exactly equal to the Fourier transform for the case when σ = 0, but this is only true when the σ = 0 line is within something called the Region of Convergence, or RoC. As you can probably gather from the name, the RoC is the area in the s plane where the Laplace transform is absolutely integrable - or another way of putting it is that the integral converges - yet another way of putting it is if you sum up the area under the absolute value of a signal you’re left with a finite value. To understand this, let’s looks at two signals; the first is the impulse response for a stable system - notice the impulse the system response dies out over time. The second is the impulse response for an unstable system - notice the system response continues to grow over time.

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We can take the Fourier transform of the stable response because after you multiply it by e− jωt , essentially multiplying it by cos(ωt)+ jsin(ωt), the signal continues to decay and therefore the integral of the absolute value produces a finite sum.

However, we can’t take the Fourier transform of the unstable response because after you multiply it by e− jωt the signal continues to grow. If you integrate this signal you get an infinite value and so it lies outside of the RoC.

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We can take the Laplace transform of an unstable impulse response, however, because there are other areas of the s plane that are within the RoC.

So far we’ve just filled out a single sliver of our s plane, the σ = 0 line. We can fill out another sliver, say the σ = −1 line, by taking our time domain signal, u(t)e−t , multiplying it by the exponential e−σt when σ = −1, and then taking the Fourier transform of the result. In this case, the two exponential functions cancel out and we’re left with just the step function, u(t). This is a trick question though because the the Fourier transform of u(t) does not converge. It’s outside of the region of convergence, however, just barely. Imagine we chose a σ that produced a near step function that is slowly decaying. With this, the Fourier transform will converge. Conversely, imagine we chose a σ that produced a near step function that is slowly growing. In this case, the Fourier transform is even further from converging than just the simple step function.

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Therefore, there was something special about the location in the s plane that produced an integral that existed right on the cusp of converging and diverging. We could graph this new line on our plot at σ = −1. You’ll see from the graph, and from the result of the Fourier transform if you do the math, that there is a point right at s = −1 that goes to infinity.

If you’ve been very keen while reading this section you’ll have realized that the impulse response of our system, u(t)e−t , produced an interesting point in the s plane at s = −1, which, for e−st , equals e−t . It’s no coincidence that both our impulse response function and the interesting point in the s plane both contain e−t . In fact, that is exactly what we’re doing with the Laplace transform; we’re probing the time domain function with e−st across the entire s plane to see what it’s made of. Basically breaking it down into its base frequencies and exponential properties. So far we’ve found one point in the s plane that produced an interesting result, but are there others? We could continue to fill out this graph manually one at a time by choosing a σ , pre-multiplying our signal by it, and taking the Fourier transform.

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I think you can see the problem with method of filling out the plane. It’ll take an infinite number of Fourier transforms, one for each of the infinite σ values, to completely fill in 3D map in the s plane. Of course the actual Laplace transform doesn’t work like this. When you solve the integral you are performing the infinite number of steps all at once, and rather than graph the resulting surface, we solve for the interesting points algebraically using the s domain function.

That is pretty awesome, right? But wait a minute you cry! The Fourier transform decomposes a function into sinusoids. Then the Laplace transform decomposes a function into both sinusoids Revision 1.3

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and exponentials. So the question is, when does the madness end? You might expect that in the next section I’ll introduce a transform that decomposes a signal into sinusoids, exponentials, and square waves. Well, we actually end right here. And there’s a good reason why. Remember we are talking about physical systems that can be modeled or approximated as linear and time invariant, and these types of systems can only be modeled using the following six operations.

In the real world, many physical parameters are related to each other through differential equations, and for LTI systems those become ordinary differential equations (ODE)16 . The important thing to note is that the solution of ordinary differential equations can only consist of sinusoids and exponentials. That’s because they are the only wave forms that don’t change shape when subjected to any combination of the six legal operations. Think about it. If you take the derivative of a sinusoid it’s still a sinusoid. If you take the integral of an exponential it’s still an exponential. So you can see how those two wave forms17 would be be the solution to equations that have the form x¨ + x˙ + x = 0. However, if you take the integral of a square wave, for example, you get a sloping step pattern, and not another square wave. So it make sense that we are defining a system’s impulse response in terms of these wave forms and only these waveforms. The ubiquity of these types of physical relationships is why the Laplace transform is one of the most important techniques you’ll learn for system analysis. 16 More

of this to come in the chapter on system identification methods it’s just the one function, est , that generates both waveforms.

17 Really

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We’ve now set up all of the background information you’ll need to really understand what makes transfer functions so powerful and exactly why they work the way they do. So let’s finally put it all together in the next section.

2.7

Putting this all Together: Transfer Functions

Coming soon!

2.8

Try This!

Coming soon!

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Chapter Credits

Meg Douglas David Feinauer Wong, C.J.

Snohomish, Washington

Gavin Kane

Northfield, VT

Emden, Germany

Krunal Desai

Zootopia

Thanks for making this chapter awesome!

82

Appendices

83

A How to Provide Feedback

So you’ve found something that you’d like fixed in this book and now you want to know how to provide feedback? Well, I’ve set up a ticketing system using JIRA, an Atlassian product, to make it easy for you. You can access the ticketing system to write a new ticket - which they call an issue - or review the status of existing tickets by going to

fundamentalsofcontroltheory.atlassian.net 1 When you click on the link the first thing you may see is the log in screen. I’m not sure why some people get it and some don’t so if you don’t see this screen then just move on to the next paragraph. If you do end up here just click on the link under the words "Log in" and it’ll take you to the System Dashboard. You can try to log in with your Atlassian credentials if you have any but it won’t work. I’ve disabled it for everyone except for anonymous users! The System Dashboard is the first screen you see when you log in. It is where you can see which issues exist against each version of the book (an errata list), where you can 1 Yes,

this is a really long URL but it’s just the title of the book so it should be easy to remember. 84

APPENDIX A. HOW TO PROVIDE FEEDBACK

add comments to those existing issues, or where you can create a brand new issue. When you click away from the system dashboard you can always get right back to it by clicking on the JIRA symbol in the upper left corner of any page. To create a new issue click on the Create button in the header bar. This will bring up the Create Issue screen. Any field that is mandatory is marked with a *.

A.1

Filling out the Create issue screen

Project: this is where you specify which book you’re writing the issue against. Since there is only a single book right now just select Fundamentals of Control Theory. Issue Type: There is also only one type of issue that you can select; Comment. This is a generic issue type that will cover all of the different types of feedback that you might want to give. Some examples of the feedback I’m hoping to receive are as follows: • Errors - There is something wrong with the content in the book. This could be as simple as a typo or something as grievous as an incorrect statement or a mathematical error. • Unclear Explanations - A phrase, paragraph, or section of the book that is too hard to understand. Perhaps I’ve worded something strangely or I’ve left out some key bit of information that would clear the concept up. • Missing Content - A section of the book is missing completely. Maybe you feel the best way to explain transfer functions is by first describing the Laplace Revision 1.3

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transform but I’ve left it out. Or perhaps every control theory textbook worth its salt should describe Mason’s rule for block diagram reduction. Let me know! Summary: This is a short one-line description of the issue that you are writing. This will help people understand the general issue at a single glance. This issue is against revision: This is a pull down menu where you can select which book you are writing the issue against. The book revisions will increase every release (about once a month) so it is important that you select the correct revision. You can find the revision on the cover page or the copyright page. Description: This is a free form text field where you can write as much as you want to describe the issue you are reporting. This is not a required field (if the summary describes the problem fully) but I’d encourage you to fill this section out so I don’t misinterpret anything. If you are reporting a section that is unclear you can use the description field to write out your recommendation for how it should be worded. Would you like to be credited in the book?: I want to make sure I acknowledge all of the help I receive for creating this book ... that is if you want to be acknowledged. This is entirely up to you. If you select yes here and I use your suggestion I’ll add your name and location to the chapter credits.

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B Transforms

B.1

Fourier Transform

Coming soon!

87

Appendix Credits

Meg Douglas

Snohomish, Washington

Thanks for making the appendix awesome!

88

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